Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Robert Richter | 1529 | 29.36% | 21 | 20.39% |
Mauro Carvalho Chehab | 1347 | 25.86% | 21 | 20.39% |
Doug Thompson | 1199 | 23.02% | 11 | 10.68% |
Borislav Petkov | 277 | 5.32% | 18 | 17.48% |
Alan Cox | 250 | 4.80% | 1 | 0.97% |
Shaun Ruffell | 145 | 2.78% | 1 | 0.97% |
Dave Jiang | 122 | 2.34% | 4 | 3.88% |
Joe Perches | 105 | 2.02% | 2 | 1.94% |
Eric Wollesen | 48 | 0.92% | 1 | 0.97% |
Yazen Ghannam | 39 | 0.75% | 1 | 0.97% |
Tony Luck | 27 | 0.52% | 2 | 1.94% |
Qiuxu Zhuo | 24 | 0.46% | 2 | 1.94% |
Toshi Kani | 18 | 0.35% | 1 | 0.97% |
Takashi Iwai | 17 | 0.33% | 2 | 1.94% |
Nicholas Krause | 8 | 0.15% | 1 | 0.97% |
Dave Peterson | 7 | 0.13% | 1 | 0.97% |
Lai Jiangshan | 6 | 0.12% | 1 | 0.97% |
Naveen Krishna Chatradhi | 6 | 0.12% | 1 | 0.97% |
Matthias Kaehlcke | 6 | 0.12% | 1 | 0.97% |
Duan Zhenzhong | 5 | 0.10% | 1 | 0.97% |
Chris Metcalf | 5 | 0.10% | 1 | 0.97% |
Dan Carpenter | 3 | 0.06% | 1 | 0.97% |
Kay Sievers | 3 | 0.06% | 1 | 0.97% |
Jean Delvare | 3 | 0.06% | 1 | 0.97% |
Aravind Gopalakrishnan | 3 | 0.06% | 1 | 0.97% |
Robert P. J. Day | 2 | 0.04% | 1 | 0.97% |
Stephen Rothwell | 2 | 0.04% | 1 | 0.97% |
Linus Torvalds | 1 | 0.02% | 1 | 0.97% |
Loc Ho | 1 | 0.02% | 1 | 0.97% |
Total | 5208 | 103 |
/* * edac_mc kernel module * (C) 2005, 2006 Linux Networx (http://lnxi.com) * This file may be distributed under the terms of the * GNU General Public License. * * Written by Thayne Harbaugh * Based on work by Dan Hollis <goemon at anime dot net> and others. * http://www.anime.net/~goemon/linux-ecc/ * * Modified by Dave Peterson and Doug Thompson * */ #include <linux/module.h> #include <linux/proc_fs.h> #include <linux/kernel.h> #include <linux/types.h> #include <linux/smp.h> #include <linux/init.h> #include <linux/sysctl.h> #include <linux/highmem.h> #include <linux/timer.h> #include <linux/slab.h> #include <linux/jiffies.h> #include <linux/spinlock.h> #include <linux/list.h> #include <linux/ctype.h> #include <linux/edac.h> #include <linux/bitops.h> #include <linux/uaccess.h> #include <asm/page.h> #include "edac_mc.h" #include "edac_module.h" #include <ras/ras_event.h> #ifdef CONFIG_EDAC_ATOMIC_SCRUB #include <asm/edac.h> #else #define edac_atomic_scrub(va, size) do { } while (0) #endif int edac_op_state = EDAC_OPSTATE_INVAL; EXPORT_SYMBOL_GPL(edac_op_state); /* lock to memory controller's control array */ static DEFINE_MUTEX(mem_ctls_mutex); static LIST_HEAD(mc_devices); /* * Used to lock EDAC MC to just one module, avoiding two drivers e. g. * apei/ghes and i7core_edac to be used at the same time. */ static const char *edac_mc_owner; static struct mem_ctl_info *error_desc_to_mci(struct edac_raw_error_desc *e) { return container_of(e, struct mem_ctl_info, error_desc); } unsigned int edac_dimm_info_location(struct dimm_info *dimm, char *buf, unsigned int len) { struct mem_ctl_info *mci = dimm->mci; int i, n, count = 0; char *p = buf; for (i = 0; i < mci->n_layers; i++) { n = snprintf(p, len, "%s %d ", edac_layer_name[mci->layers[i].type], dimm->location[i]); p += n; len -= n; count += n; if (!len) break; } return count; } #ifdef CONFIG_EDAC_DEBUG static void edac_mc_dump_channel(struct rank_info *chan) { edac_dbg(4, " channel->chan_idx = %d\n", chan->chan_idx); edac_dbg(4, " channel = %p\n", chan); edac_dbg(4, " channel->csrow = %p\n", chan->csrow); edac_dbg(4, " channel->dimm = %p\n", chan->dimm); } static void edac_mc_dump_dimm(struct dimm_info *dimm) { char location[80]; if (!dimm->nr_pages) return; edac_dimm_info_location(dimm, location, sizeof(location)); edac_dbg(4, "%s%i: %smapped as virtual row %d, chan %d\n", dimm->mci->csbased ? "rank" : "dimm", dimm->idx, location, dimm->csrow, dimm->cschannel); edac_dbg(4, " dimm = %p\n", dimm); edac_dbg(4, " dimm->label = '%s'\n", dimm->label); edac_dbg(4, " dimm->nr_pages = 0x%x\n", dimm->nr_pages); edac_dbg(4, " dimm->grain = %d\n", dimm->grain); edac_dbg(4, " dimm->nr_pages = 0x%x\n", dimm->nr_pages); } static void edac_mc_dump_csrow(struct csrow_info *csrow) { edac_dbg(4, "csrow->csrow_idx = %d\n", csrow->csrow_idx); edac_dbg(4, " csrow = %p\n", csrow); edac_dbg(4, " csrow->first_page = 0x%lx\n", csrow->first_page); edac_dbg(4, " csrow->last_page = 0x%lx\n", csrow->last_page); edac_dbg(4, " csrow->page_mask = 0x%lx\n", csrow->page_mask); edac_dbg(4, " csrow->nr_channels = %d\n", csrow->nr_channels); edac_dbg(4, " csrow->channels = %p\n", csrow->channels); edac_dbg(4, " csrow->mci = %p\n", csrow->mci); } static void edac_mc_dump_mci(struct mem_ctl_info *mci) { edac_dbg(3, "\tmci = %p\n", mci); edac_dbg(3, "\tmci->mtype_cap = %lx\n", mci->mtype_cap); edac_dbg(3, "\tmci->edac_ctl_cap = %lx\n", mci->edac_ctl_cap); edac_dbg(3, "\tmci->edac_cap = %lx\n", mci->edac_cap); edac_dbg(4, "\tmci->edac_check = %p\n", mci->edac_check); edac_dbg(3, "\tmci->nr_csrows = %d, csrows = %p\n", mci->nr_csrows, mci->csrows); edac_dbg(3, "\tmci->nr_dimms = %d, dimms = %p\n", mci->tot_dimms, mci->dimms); edac_dbg(3, "\tdev = %p\n", mci->pdev); edac_dbg(3, "\tmod_name:ctl_name = %s:%s\n", mci->mod_name, mci->ctl_name); edac_dbg(3, "\tpvt_info = %p\n\n", mci->pvt_info); } #endif /* CONFIG_EDAC_DEBUG */ const char * const edac_mem_types[] = { [MEM_EMPTY] = "Empty", [MEM_RESERVED] = "Reserved", [MEM_UNKNOWN] = "Unknown", [MEM_FPM] = "FPM", [MEM_EDO] = "EDO", [MEM_BEDO] = "BEDO", [MEM_SDR] = "Unbuffered-SDR", [MEM_RDR] = "Registered-SDR", [MEM_DDR] = "Unbuffered-DDR", [MEM_RDDR] = "Registered-DDR", [MEM_RMBS] = "RMBS", [MEM_DDR2] = "Unbuffered-DDR2", [MEM_FB_DDR2] = "FullyBuffered-DDR2", [MEM_RDDR2] = "Registered-DDR2", [MEM_XDR] = "XDR", [MEM_DDR3] = "Unbuffered-DDR3", [MEM_RDDR3] = "Registered-DDR3", [MEM_LRDDR3] = "Load-Reduced-DDR3-RAM", [MEM_LPDDR3] = "Low-Power-DDR3-RAM", [MEM_DDR4] = "Unbuffered-DDR4", [MEM_RDDR4] = "Registered-DDR4", [MEM_LPDDR4] = "Low-Power-DDR4-RAM", [MEM_LRDDR4] = "Load-Reduced-DDR4-RAM", [MEM_DDR5] = "Unbuffered-DDR5", [MEM_NVDIMM] = "Non-volatile-RAM", [MEM_WIO2] = "Wide-IO-2", [MEM_HBM2] = "High-bandwidth-memory-Gen2", }; EXPORT_SYMBOL_GPL(edac_mem_types); /** * edac_align_ptr - Prepares the pointer offsets for a single-shot allocation * @p: pointer to a pointer with the memory offset to be used. At * return, this will be incremented to point to the next offset * @size: Size of the data structure to be reserved * @n_elems: Number of elements that should be reserved * * If 'size' is a constant, the compiler will optimize this whole function * down to either a no-op or the addition of a constant to the value of '*p'. * * The 'p' pointer is absolutely needed to keep the proper advancing * further in memory to the proper offsets when allocating the struct along * with its embedded structs, as edac_device_alloc_ctl_info() does it * above, for example. * * At return, the pointer 'p' will be incremented to be used on a next call * to this function. */ void *edac_align_ptr(void **p, unsigned int size, int n_elems) { unsigned int align, r; void *ptr = *p; *p += size * n_elems; /* * 'p' can possibly be an unaligned item X such that sizeof(X) is * 'size'. Adjust 'p' so that its alignment is at least as * stringent as what the compiler would provide for X and return * the aligned result. * Here we assume that the alignment of a "long long" is the most * stringent alignment that the compiler will ever provide by default. * As far as I know, this is a reasonable assumption. */ if (size > sizeof(long)) align = sizeof(long long); else if (size > sizeof(int)) align = sizeof(long); else if (size > sizeof(short)) align = sizeof(int); else if (size > sizeof(char)) align = sizeof(short); else return (char *)ptr; r = (unsigned long)p % align; if (r == 0) return (char *)ptr; *p += align - r; return (void *)(((unsigned long)ptr) + align - r); } static void _edac_mc_free(struct mem_ctl_info *mci) { put_device(&mci->dev); } static void mci_release(struct device *dev) { struct mem_ctl_info *mci = container_of(dev, struct mem_ctl_info, dev); struct csrow_info *csr; int i, chn, row; if (mci->dimms) { for (i = 0; i < mci->tot_dimms; i++) kfree(mci->dimms[i]); kfree(mci->dimms); } if (mci->csrows) { for (row = 0; row < mci->nr_csrows; row++) { csr = mci->csrows[row]; if (!csr) continue; if (csr->channels) { for (chn = 0; chn < mci->num_cschannel; chn++) kfree(csr->channels[chn]); kfree(csr->channels); } kfree(csr); } kfree(mci->csrows); } kfree(mci); } static int edac_mc_alloc_csrows(struct mem_ctl_info *mci) { unsigned int tot_channels = mci->num_cschannel; unsigned int tot_csrows = mci->nr_csrows; unsigned int row, chn; /* * Alocate and fill the csrow/channels structs */ mci->csrows = kcalloc(tot_csrows, sizeof(*mci->csrows), GFP_KERNEL); if (!mci->csrows) return -ENOMEM; for (row = 0; row < tot_csrows; row++) { struct csrow_info *csr; csr = kzalloc(sizeof(**mci->csrows), GFP_KERNEL); if (!csr) return -ENOMEM; mci->csrows[row] = csr; csr->csrow_idx = row; csr->mci = mci; csr->nr_channels = tot_channels; csr->channels = kcalloc(tot_channels, sizeof(*csr->channels), GFP_KERNEL); if (!csr->channels) return -ENOMEM; for (chn = 0; chn < tot_channels; chn++) { struct rank_info *chan; chan = kzalloc(sizeof(**csr->channels), GFP_KERNEL); if (!chan) return -ENOMEM; csr->channels[chn] = chan; chan->chan_idx = chn; chan->csrow = csr; } } return 0; } static int edac_mc_alloc_dimms(struct mem_ctl_info *mci) { unsigned int pos[EDAC_MAX_LAYERS]; unsigned int row, chn, idx; int layer; void *p; /* * Allocate and fill the dimm structs */ mci->dimms = kcalloc(mci->tot_dimms, sizeof(*mci->dimms), GFP_KERNEL); if (!mci->dimms) return -ENOMEM; memset(&pos, 0, sizeof(pos)); row = 0; chn = 0; for (idx = 0; idx < mci->tot_dimms; idx++) { struct dimm_info *dimm; struct rank_info *chan; int n, len; chan = mci->csrows[row]->channels[chn]; dimm = kzalloc(sizeof(**mci->dimms), GFP_KERNEL); if (!dimm) return -ENOMEM; mci->dimms[idx] = dimm; dimm->mci = mci; dimm->idx = idx; /* * Copy DIMM location and initialize it. */ len = sizeof(dimm->label); p = dimm->label; n = snprintf(p, len, "mc#%u", mci->mc_idx); p += n; len -= n; for (layer = 0; layer < mci->n_layers; layer++) { n = snprintf(p, len, "%s#%u", edac_layer_name[mci->layers[layer].type], pos[layer]); p += n; len -= n; dimm->location[layer] = pos[layer]; if (len <= 0) break; } /* Link it to the csrows old API data */ chan->dimm = dimm; dimm->csrow = row; dimm->cschannel = chn; /* Increment csrow location */ if (mci->layers[0].is_virt_csrow) { chn++; if (chn == mci->num_cschannel) { chn = 0; row++; } } else { row++; if (row == mci->nr_csrows) { row = 0; chn++; } } /* Increment dimm location */ for (layer = mci->n_layers - 1; layer >= 0; layer--) { pos[layer]++; if (pos[layer] < mci->layers[layer].size) break; pos[layer] = 0; } } return 0; } struct mem_ctl_info *edac_mc_alloc(unsigned int mc_num, unsigned int n_layers, struct edac_mc_layer *layers, unsigned int sz_pvt) { struct mem_ctl_info *mci; struct edac_mc_layer *layer; unsigned int idx, size, tot_dimms = 1; unsigned int tot_csrows = 1, tot_channels = 1; void *pvt, *ptr = NULL; bool per_rank = false; if (WARN_ON(n_layers > EDAC_MAX_LAYERS || n_layers == 0)) return NULL; /* * Calculate the total amount of dimms and csrows/cschannels while * in the old API emulation mode */ for (idx = 0; idx < n_layers; idx++) { tot_dimms *= layers[idx].size; if (layers[idx].is_virt_csrow) tot_csrows *= layers[idx].size; else tot_channels *= layers[idx].size; if (layers[idx].type == EDAC_MC_LAYER_CHIP_SELECT) per_rank = true; } /* Figure out the offsets of the various items from the start of an mc * structure. We want the alignment of each item to be at least as * stringent as what the compiler would provide if we could simply * hardcode everything into a single struct. */ mci = edac_align_ptr(&ptr, sizeof(*mci), 1); layer = edac_align_ptr(&ptr, sizeof(*layer), n_layers); pvt = edac_align_ptr(&ptr, sz_pvt, 1); size = ((unsigned long)pvt) + sz_pvt; edac_dbg(1, "allocating %u bytes for mci data (%d %s, %d csrows/channels)\n", size, tot_dimms, per_rank ? "ranks" : "dimms", tot_csrows * tot_channels); mci = kzalloc(size, GFP_KERNEL); if (mci == NULL) return NULL; mci->dev.release = mci_release; device_initialize(&mci->dev); /* Adjust pointers so they point within the memory we just allocated * rather than an imaginary chunk of memory located at address 0. */ layer = (struct edac_mc_layer *)(((char *)mci) + ((unsigned long)layer)); pvt = sz_pvt ? (((char *)mci) + ((unsigned long)pvt)) : NULL; /* setup index and various internal pointers */ mci->mc_idx = mc_num; mci->tot_dimms = tot_dimms; mci->pvt_info = pvt; mci->n_layers = n_layers; mci->layers = layer; memcpy(mci->layers, layers, sizeof(*layer) * n_layers); mci->nr_csrows = tot_csrows; mci->num_cschannel = tot_channels; mci->csbased = per_rank; if (edac_mc_alloc_csrows(mci)) goto error; if (edac_mc_alloc_dimms(mci)) goto error; mci->op_state = OP_ALLOC; return mci; error: _edac_mc_free(mci); return NULL; } EXPORT_SYMBOL_GPL(edac_mc_alloc); void edac_mc_free(struct mem_ctl_info *mci) { edac_dbg(1, "\n"); _edac_mc_free(mci); } EXPORT_SYMBOL_GPL(edac_mc_free); bool edac_has_mcs(void) { bool ret; mutex_lock(&mem_ctls_mutex); ret = list_empty(&mc_devices); mutex_unlock(&mem_ctls_mutex); return !ret; } EXPORT_SYMBOL_GPL(edac_has_mcs); /* Caller must hold mem_ctls_mutex */ static struct mem_ctl_info *__find_mci_by_dev(struct device *dev) { struct mem_ctl_info *mci; struct list_head *item; edac_dbg(3, "\n"); list_for_each(item, &mc_devices) { mci = list_entry(item, struct mem_ctl_info, link); if (mci->pdev == dev) return mci; } return NULL; } /** * find_mci_by_dev * * scan list of controllers looking for the one that manages * the 'dev' device * @dev: pointer to a struct device related with the MCI */ struct mem_ctl_info *find_mci_by_dev(struct device *dev) { struct mem_ctl_info *ret; mutex_lock(&mem_ctls_mutex); ret = __find_mci_by_dev(dev); mutex_unlock(&mem_ctls_mutex); return ret; } EXPORT_SYMBOL_GPL(find_mci_by_dev); /* * edac_mc_workq_function * performs the operation scheduled by a workq request */ static void edac_mc_workq_function(struct work_struct *work_req) { struct delayed_work *d_work = to_delayed_work(work_req); struct mem_ctl_info *mci = to_edac_mem_ctl_work(d_work); mutex_lock(&mem_ctls_mutex); if (mci->op_state != OP_RUNNING_POLL) { mutex_unlock(&mem_ctls_mutex); return; } if (edac_op_state == EDAC_OPSTATE_POLL) mci->edac_check(mci); mutex_unlock(&mem_ctls_mutex); /* Queue ourselves again. */ edac_queue_work(&mci->work, msecs_to_jiffies(edac_mc_get_poll_msec())); } /* * edac_mc_reset_delay_period(unsigned long value) * * user space has updated our poll period value, need to * reset our workq delays */ void edac_mc_reset_delay_period(unsigned long value) { struct mem_ctl_info *mci; struct list_head *item; mutex_lock(&mem_ctls_mutex); list_for_each(item, &mc_devices) { mci = list_entry(item, struct mem_ctl_info, link); if (mci->op_state == OP_RUNNING_POLL) edac_mod_work(&mci->work, value); } mutex_unlock(&mem_ctls_mutex); } /* Return 0 on success, 1 on failure. * Before calling this function, caller must * assign a unique value to mci->mc_idx. * * locking model: * * called with the mem_ctls_mutex lock held */ static int add_mc_to_global_list(struct mem_ctl_info *mci) { struct list_head *item, *insert_before; struct mem_ctl_info *p; insert_before = &mc_devices; p = __find_mci_by_dev(mci->pdev); if (unlikely(p != NULL)) goto fail0; list_for_each(item, &mc_devices) { p = list_entry(item, struct mem_ctl_info, link); if (p->mc_idx >= mci->mc_idx) { if (unlikely(p->mc_idx == mci->mc_idx)) goto fail1; insert_before = item; break; } } list_add_tail_rcu(&mci->link, insert_before); return 0; fail0: edac_printk(KERN_WARNING, EDAC_MC, "%s (%s) %s %s already assigned %d\n", dev_name(p->pdev), edac_dev_name(mci), p->mod_name, p->ctl_name, p->mc_idx); return 1; fail1: edac_printk(KERN_WARNING, EDAC_MC, "bug in low-level driver: attempt to assign\n" " duplicate mc_idx %d in %s()\n", p->mc_idx, __func__); return 1; } static int del_mc_from_global_list(struct mem_ctl_info *mci) { list_del_rcu(&mci->link); /* these are for safe removal of devices from global list while * NMI handlers may be traversing list */ synchronize_rcu(); INIT_LIST_HEAD(&mci->link); return list_empty(&mc_devices); } struct mem_ctl_info *edac_mc_find(int idx) { struct mem_ctl_info *mci; struct list_head *item; mutex_lock(&mem_ctls_mutex); list_for_each(item, &mc_devices) { mci = list_entry(item, struct mem_ctl_info, link); if (mci->mc_idx == idx) goto unlock; } mci = NULL; unlock: mutex_unlock(&mem_ctls_mutex); return mci; } EXPORT_SYMBOL(edac_mc_find); const char *edac_get_owner(void) { return edac_mc_owner; } EXPORT_SYMBOL_GPL(edac_get_owner); /* FIXME - should a warning be printed if no error detection? correction? */ int edac_mc_add_mc_with_groups(struct mem_ctl_info *mci, const struct attribute_group **groups) { int ret = -EINVAL; edac_dbg(0, "\n"); #ifdef CONFIG_EDAC_DEBUG if (edac_debug_level >= 3) edac_mc_dump_mci(mci); if (edac_debug_level >= 4) { struct dimm_info *dimm; int i; for (i = 0; i < mci->nr_csrows; i++) { struct csrow_info *csrow = mci->csrows[i]; u32 nr_pages = 0; int j; for (j = 0; j < csrow->nr_channels; j++) nr_pages += csrow->channels[j]->dimm->nr_pages; if (!nr_pages) continue; edac_mc_dump_csrow(csrow); for (j = 0; j < csrow->nr_channels; j++) if (csrow->channels[j]->dimm->nr_pages) edac_mc_dump_channel(csrow->channels[j]); } mci_for_each_dimm(mci, dimm) edac_mc_dump_dimm(dimm); } #endif mutex_lock(&mem_ctls_mutex); if (edac_mc_owner && edac_mc_owner != mci->mod_name) { ret = -EPERM; goto fail0; } if (add_mc_to_global_list(mci)) goto fail0; /* set load time so that error rate can be tracked */ mci->start_time = jiffies; mci->bus = edac_get_sysfs_subsys(); if (edac_create_sysfs_mci_device(mci, groups)) { edac_mc_printk(mci, KERN_WARNING, "failed to create sysfs device\n"); goto fail1; } if (mci->edac_check) { mci->op_state = OP_RUNNING_POLL; INIT_DELAYED_WORK(&mci->work, edac_mc_workq_function); edac_queue_work(&mci->work, msecs_to_jiffies(edac_mc_get_poll_msec())); } else { mci->op_state = OP_RUNNING_INTERRUPT; } /* Report action taken */ edac_mc_printk(mci, KERN_INFO, "Giving out device to module %s controller %s: DEV %s (%s)\n", mci->mod_name, mci->ctl_name, mci->dev_name, edac_op_state_to_string(mci->op_state)); edac_mc_owner = mci->mod_name; mutex_unlock(&mem_ctls_mutex); return 0; fail1: del_mc_from_global_list(mci); fail0: mutex_unlock(&mem_ctls_mutex); return ret; } EXPORT_SYMBOL_GPL(edac_mc_add_mc_with_groups); struct mem_ctl_info *edac_mc_del_mc(struct device *dev) { struct mem_ctl_info *mci; edac_dbg(0, "\n"); mutex_lock(&mem_ctls_mutex); /* find the requested mci struct in the global list */ mci = __find_mci_by_dev(dev); if (mci == NULL) { mutex_unlock(&mem_ctls_mutex); return NULL; } /* mark MCI offline: */ mci->op_state = OP_OFFLINE; if (del_mc_from_global_list(mci)) edac_mc_owner = NULL; mutex_unlock(&mem_ctls_mutex); if (mci->edac_check) edac_stop_work(&mci->work); /* remove from sysfs */ edac_remove_sysfs_mci_device(mci); edac_printk(KERN_INFO, EDAC_MC, "Removed device %d for %s %s: DEV %s\n", mci->mc_idx, mci->mod_name, mci->ctl_name, edac_dev_name(mci)); return mci; } EXPORT_SYMBOL_GPL(edac_mc_del_mc); static void edac_mc_scrub_block(unsigned long page, unsigned long offset, u32 size) { struct page *pg; void *virt_addr; unsigned long flags = 0; edac_dbg(3, "\n"); /* ECC error page was not in our memory. Ignore it. */ if (!pfn_valid(page)) return; /* Find the actual page structure then map it and fix */ pg = pfn_to_page(page); if (PageHighMem(pg)) local_irq_save(flags); virt_addr = kmap_atomic(pg); /* Perform architecture specific atomic scrub operation */ edac_atomic_scrub(virt_addr + offset, size); /* Unmap and complete */ kunmap_atomic(virt_addr); if (PageHighMem(pg)) local_irq_restore(flags); } /* FIXME - should return -1 */ int edac_mc_find_csrow_by_page(struct mem_ctl_info *mci, unsigned long page) { struct csrow_info **csrows = mci->csrows; int row, i, j, n; edac_dbg(1, "MC%d: 0x%lx\n", mci->mc_idx, page); row = -1; for (i = 0; i < mci->nr_csrows; i++) { struct csrow_info *csrow = csrows[i]; n = 0; for (j = 0; j < csrow->nr_channels; j++) { struct dimm_info *dimm = csrow->channels[j]->dimm; n += dimm->nr_pages; } if (n == 0) continue; edac_dbg(3, "MC%d: first(0x%lx) page(0x%lx) last(0x%lx) mask(0x%lx)\n", mci->mc_idx, csrow->first_page, page, csrow->last_page, csrow->page_mask); if ((page >= csrow->first_page) && (page <= csrow->last_page) && ((page & csrow->page_mask) == (csrow->first_page & csrow->page_mask))) { row = i; break; } } if (row == -1) edac_mc_printk(mci, KERN_ERR, "could not look up page error address %lx\n", (unsigned long)page); return row; } EXPORT_SYMBOL_GPL(edac_mc_find_csrow_by_page); const char *edac_layer_name[] = { [EDAC_MC_LAYER_BRANCH] = "branch", [EDAC_MC_LAYER_CHANNEL] = "channel", [EDAC_MC_LAYER_SLOT] = "slot", [EDAC_MC_LAYER_CHIP_SELECT] = "csrow", [EDAC_MC_LAYER_ALL_MEM] = "memory", }; EXPORT_SYMBOL_GPL(edac_layer_name); static void edac_inc_ce_error(struct edac_raw_error_desc *e) { int pos[EDAC_MAX_LAYERS] = { e->top_layer, e->mid_layer, e->low_layer }; struct mem_ctl_info *mci = error_desc_to_mci(e); struct dimm_info *dimm = edac_get_dimm(mci, pos[0], pos[1], pos[2]); mci->ce_mc += e->error_count; if (dimm) dimm->ce_count += e->error_count; else mci->ce_noinfo_count += e->error_count; } static void edac_inc_ue_error(struct edac_raw_error_desc *e) { int pos[EDAC_MAX_LAYERS] = { e->top_layer, e->mid_layer, e->low_layer }; struct mem_ctl_info *mci = error_desc_to_mci(e); struct dimm_info *dimm = edac_get_dimm(mci, pos[0], pos[1], pos[2]); mci->ue_mc += e->error_count; if (dimm) dimm->ue_count += e->error_count; else mci->ue_noinfo_count += e->error_count; } static void edac_ce_error(struct edac_raw_error_desc *e) { struct mem_ctl_info *mci = error_desc_to_mci(e); unsigned long remapped_page; if (edac_mc_get_log_ce()) { edac_mc_printk(mci, KERN_WARNING, "%d CE %s%son %s (%s page:0x%lx offset:0x%lx grain:%ld syndrome:0x%lx%s%s)\n", e->error_count, e->msg, *e->msg ? " " : "", e->label, e->location, e->page_frame_number, e->offset_in_page, e->grain, e->syndrome, *e->other_detail ? " - " : "", e->other_detail); } edac_inc_ce_error(e); if (mci->scrub_mode == SCRUB_SW_SRC) { /* * Some memory controllers (called MCs below) can remap * memory so that it is still available at a different * address when PCI devices map into memory. * MC's that can't do this, lose the memory where PCI * devices are mapped. This mapping is MC-dependent * and so we call back into the MC driver for it to * map the MC page to a physical (CPU) page which can * then be mapped to a virtual page - which can then * be scrubbed. */ remapped_page = mci->ctl_page_to_phys ? mci->ctl_page_to_phys(mci, e->page_frame_number) : e->page_frame_number; edac_mc_scrub_block(remapped_page, e->offset_in_page, e->grain); } } static void edac_ue_error(struct edac_raw_error_desc *e) { struct mem_ctl_info *mci = error_desc_to_mci(e); if (edac_mc_get_log_ue()) { edac_mc_printk(mci, KERN_WARNING, "%d UE %s%son %s (%s page:0x%lx offset:0x%lx grain:%ld%s%s)\n", e->error_count, e->msg, *e->msg ? " " : "", e->label, e->location, e->page_frame_number, e->offset_in_page, e->grain, *e->other_detail ? " - " : "", e->other_detail); } edac_inc_ue_error(e); if (edac_mc_get_panic_on_ue()) { panic("UE %s%son %s (%s page:0x%lx offset:0x%lx grain:%ld%s%s)\n", e->msg, *e->msg ? " " : "", e->label, e->location, e->page_frame_number, e->offset_in_page, e->grain, *e->other_detail ? " - " : "", e->other_detail); } } static void edac_inc_csrow(struct edac_raw_error_desc *e, int row, int chan) { struct mem_ctl_info *mci = error_desc_to_mci(e); enum hw_event_mc_err_type type = e->type; u16 count = e->error_count; if (row < 0) return; edac_dbg(4, "csrow/channel to increment: (%d,%d)\n", row, chan); if (type == HW_EVENT_ERR_CORRECTED) { mci->csrows[row]->ce_count += count; if (chan >= 0) mci->csrows[row]->channels[chan]->ce_count += count; } else { mci->csrows[row]->ue_count += count; } } void edac_raw_mc_handle_error(struct edac_raw_error_desc *e) { struct mem_ctl_info *mci = error_desc_to_mci(e); u8 grain_bits; /* Sanity-check driver-supplied grain value. */ if (WARN_ON_ONCE(!e->grain)) e->grain = 1; grain_bits = fls_long(e->grain - 1); /* Report the error via the trace interface */ if (IS_ENABLED(CONFIG_RAS)) trace_mc_event(e->type, e->msg, e->label, e->error_count, mci->mc_idx, e->top_layer, e->mid_layer, e->low_layer, (e->page_frame_number << PAGE_SHIFT) | e->offset_in_page, grain_bits, e->syndrome, e->other_detail); if (e->type == HW_EVENT_ERR_CORRECTED) edac_ce_error(e); else edac_ue_error(e); } EXPORT_SYMBOL_GPL(edac_raw_mc_handle_error); void edac_mc_handle_error(const enum hw_event_mc_err_type type, struct mem_ctl_info *mci, const u16 error_count, const unsigned long page_frame_number, const unsigned long offset_in_page, const unsigned long syndrome, const int top_layer, const int mid_layer, const int low_layer, const char *msg, const char *other_detail) { struct dimm_info *dimm; char *p; int row = -1, chan = -1; int pos[EDAC_MAX_LAYERS] = { top_layer, mid_layer, low_layer }; int i, n_labels = 0; struct edac_raw_error_desc *e = &mci->error_desc; bool any_memory = true; edac_dbg(3, "MC%d\n", mci->mc_idx); /* Fills the error report buffer */ memset(e, 0, sizeof (*e)); e->error_count = error_count; e->type = type; e->top_layer = top_layer; e->mid_layer = mid_layer; e->low_layer = low_layer; e->page_frame_number = page_frame_number; e->offset_in_page = offset_in_page; e->syndrome = syndrome; /* need valid strings here for both: */ e->msg = msg ?: ""; e->other_detail = other_detail ?: ""; /* * Check if the event report is consistent and if the memory location is * known. If it is, the DIMM(s) label info will be filled and the DIMM's * error counters will be incremented. */ for (i = 0; i < mci->n_layers; i++) { if (pos[i] >= (int)mci->layers[i].size) { edac_mc_printk(mci, KERN_ERR, "INTERNAL ERROR: %s value is out of range (%d >= %d)\n", edac_layer_name[mci->layers[i].type], pos[i], mci->layers[i].size); /* * Instead of just returning it, let's use what's * known about the error. The increment routines and * the DIMM filter logic will do the right thing by * pointing the likely damaged DIMMs. */ pos[i] = -1; } if (pos[i] >= 0) any_memory = false; } /* * Get the dimm label/grain that applies to the match criteria. * As the error algorithm may not be able to point to just one memory * stick, the logic here will get all possible labels that could * pottentially be affected by the error. * On FB-DIMM memory controllers, for uncorrected errors, it is common * to have only the MC channel and the MC dimm (also called "branch") * but the channel is not known, as the memory is arranged in pairs, * where each memory belongs to a separate channel within the same * branch. */ p = e->label; *p = '\0'; mci_for_each_dimm(mci, dimm) { if (top_layer >= 0 && top_layer != dimm->location[0]) continue; if (mid_layer >= 0 && mid_layer != dimm->location[1]) continue; if (low_layer >= 0 && low_layer != dimm->location[2]) continue; /* get the max grain, over the error match range */ if (dimm->grain > e->grain) e->grain = dimm->grain; /* * If the error is memory-controller wide, there's no need to * seek for the affected DIMMs because the whole channel/memory * controller/... may be affected. Also, don't show errors for * empty DIMM slots. */ if (!dimm->nr_pages) continue; n_labels++; if (n_labels > EDAC_MAX_LABELS) { p = e->label; *p = '\0'; } else { if (p != e->label) { strcpy(p, OTHER_LABEL); p += strlen(OTHER_LABEL); } strcpy(p, dimm->label); p += strlen(p); } /* * get csrow/channel of the DIMM, in order to allow * incrementing the compat API counters */ edac_dbg(4, "%s csrows map: (%d,%d)\n", mci->csbased ? "rank" : "dimm", dimm->csrow, dimm->cschannel); if (row == -1) row = dimm->csrow; else if (row >= 0 && row != dimm->csrow) row = -2; if (chan == -1) chan = dimm->cschannel; else if (chan >= 0 && chan != dimm->cschannel) chan = -2; } if (any_memory) strcpy(e->label, "any memory"); else if (!*e->label) strcpy(e->label, "unknown memory"); edac_inc_csrow(e, row, chan); /* Fill the RAM location data */ p = e->location; for (i = 0; i < mci->n_layers; i++) { if (pos[i] < 0) continue; p += sprintf(p, "%s:%d ", edac_layer_name[mci->layers[i].type], pos[i]); } if (p > e->location) *(p - 1) = '\0'; edac_raw_mc_handle_error(e); } EXPORT_SYMBOL_GPL(edac_mc_handle_error);
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